JPH0733088B2 - Inkjet head - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an inkjet head capable of recording by ejecting ink droplets from a nozzle and flying to deposit ink on recording paper, and more specifically to an ink tank integrated with an ink tank. The present invention relates to a disposable inkjet head.

(Prior Art) Conventionally, the one described in JP-A-59-207263 is known as a disposable type inkjet head,
The conventional example has a shrinkable ink reservoir formed of a flexible silicone rubber or the like as a constituent element.
The ink pool shrinks as the ink is consumed, but on the other hand, it tries to return to its original shape, and tries to draw in the meniscus of the ink formed in the nozzle portion due to the surface tension of the ink. Therefore, the ejection from the nozzle portion becomes unstable, the ejected ink droplets become small, and the flying speed and direction of the ink droplets become improper, which causes a problem that normal printing cannot be performed. It was Further, when the ink consumption continues, the restoring force of the ink reservoir becomes stronger, the ink suction force at the nozzle portion becomes stronger, and it becomes impossible for the ink to form a meniscus at the nozzle portion due to the surface tension. As a result, air may enter from the nozzle portion into the head, and the ink may not be ejected even though a considerable amount of the ink remains in the ink reservoir.

Further, as a general problem of the inkjet head, since the ink is not rapidly supplied to the inside of the nozzle immediately after ejecting the ink from the nozzle, air enters the inside of the head from the nozzle and stays near the nozzle portion as bubbles. There was a problem that it hindered ink ejection.

(Problems to be Solved by the Invention) According to the present invention, the ejection of ink from the nozzle portion is stable, and even if air enters the head from the nozzle portion and bubbles are generated, the ink remains in the head. In addition, a disposable ink tank integrated ink jet head that does not eject from the nozzle when the air that has replaced the ink in the ink tank expands due to temperature rise etc. and pushes out the ink is also provided. To aim.

(Means for Solving the Problem) In order to achieve the above object, the ink jet head of the present invention has a space above the middle of the shaft cylinder as an ink reservoir,
An ink reservoir for retaining the ink pushed out from the ink reservoir due to the expansion of the air in the ink reservoir is installed in the space below it, and a nozzle and means for ejecting ink droplets from the nozzle are provided on the outside of the barrel. It is characterized in that an ink channel is additionally provided and an ink flow path for supplying ink from the ink reservoir to the means for ejecting the ink droplet is provided near the boundary between the ink reservoir and the ink reservoir.

Embodiment An embodiment of the present invention will be described with reference to the drawings. First, a base plate (2) is attached to the outside of the shaft cylinder (1), and a nozzle plate (3) having a plurality of nozzles perforated in the base plate (2) is appropriately provided via a gap plate (4). It is joined with a large gap (5).

Heat generating resistors (not shown) are arranged on the substrate (2) at positions facing the nozzles (8), and each heat generating resistor is connected to a contact (7) by a wiring (6).

In the middle of the barrel (1), an ink flow path (9) is provided which communicates with the substrate (2) from the inside through the substrate (2) and the gap (5) between the nozzle plate (3). Further, a space above the vicinity of the ink flow path (9) of the shaft cylinder (1) is provided as an ink reservoir (10), and below that, an ink retainer (11) is incorporated.

The ink storage body (11) is provided with a large number of horizontal wings (12) on its outer peripheral portion, and an ink storage groove (13) having a width such that a capillary phenomenon occurs between the wings (12). Is formed, and the vertical groove (14) that connects the ink reservoir (10) and the ink reservoir groove (13) in the vertical direction is formed to have a width that causes a capillary phenomenon, and is opposite to the groove (14). Each wing (12) has a cutout on the side to form a ventilation path (15). The width of the ink retaining groove (13) is gradually increased from the upper side to the lower side, and the capillary action is stronger than that in the upper side. An air port (16) is opened at the lower end of the ink retainer (11), and the air port (16) communicates with the ink reservoir (10) through the ventilation passage (15) and the vertical groove (14). is doing.

Of course, the ink reservoir (10) is filled with ink,
The barrel (1) is made of a transparent material so that the ink amount can be visually recognized from the outside. In this embodiment, the entire ink jet head is configured to be disposable, but the ink reservoir (10) may be made into a cartridge to be an ink tank exchange type. The ink (17) is supplied from the ink flow path (9) to the gap (5) between the nozzle plate (3) and the substrate (2) and is generated when a thermal pulse is applied from a required heating resistor by an information signal. It is ejected from the nozzle (8) at a position corresponding to the heating resistor according to the state change and adhered to the recording paper. The internal space of the ink reservoir (10) is slightly negative pressure, and when the ink is consumed, the negative pressure is further negative, and when the ink exceeds a certain value, the air port (16) passes through the ventilation path (15) and the vertical direction. Air flows through the groove (14) into the ink reservoir (10) and returns to the original pressure. In this case, the fluctuation of the pressure is very small, and it is given to the ink meniscus in the nozzle (8). The effect is practically not a problem. Further, the ink pressure in the nozzle (8) is determined by the difference in height between the nozzle (8) and the upper end position (a) of the vertical groove (14) and the vertical direction (that is, this difference is the ink in the nozzle portion). Since it is not related to the height of the ink surface in the ink reservoir (10), the ink pressure in the nozzle (8) is always constant regardless of the amount of ink consumed. Therefore, the ejection of ink from the nozzle (8) is extremely stable. In addition, immediately after the ink is ejected from the nozzle (8), the nozzle (8)
Even if air flows from the head to the inside of the head and bubbles are generated, the bubbles escape through the ink flow path (9) and into the ink reservoir (10). Therefore, between the nozzle plate (3) and the substrate (2). It does not stay in the gap (5) and does not hinder the ink ejection from the nozzle (8).

Further, even if the air in the ink reservoir (10) expands due to temperature rise or the like and pushes out the ink, the ink enters the ink retaining groove (13) of the ink retainer (11) through the vertical groove (14) and is retained. Therefore, the ink is not ejected unintentionally from the nozzle (8). The ink that has entered the ink retaining groove (13) is drawn back into the original ink reservoir (10) by contracting as the air in the ink reservoir (10) returns to its original state.

(Advantages of the Invention) The present invention is as described above, and the ejection of ink from the nozzle is extremely stable, and even if air may enter from the nozzle into the head and bubbles may be generated, the bubbles immediately form the ink. Since it escapes to the reservoir, it does not hinder the ejection of ink, and even if the air in the ink reservoir expands due to a rise in temperature and the ink is pushed out, it is absorbed by the ink retainer and is unintentionally ejected from the nozzle. This has the effect of preventing accidents such as discharge to the outside.

[Brief description of drawings]

1 is a front view, FIG. 2 is a longitudinal sectional view, FIG. 3 is a lateral sectional view taken along the line AA of FIG. 2, and FIG. 4 is a lateral sectional view taken along the line BB of FIG. (1) …… Shaft cylinder, (2) …… Substrate, (3) …… Nozzle plate, (4) …… Gap plate, (5) …… Gap, (6) …… Wiring, (7) …… Contact point, (8) ... Nozzle, (9) ... Ink flow path, (10) ... Ink reservoir, (11) ... Ink retainer, (12) ... Feather, (13) ... Ink retainer Reservoir, (1
4) …… Vertical groove, (15) …… Ventilation path, (16) …… Air port,
(17) …… Ink.

Claims (1)

[Claims] 1. A space above the middle of the shaft cylinder is defined as an ink reservoir, and a space below it is provided with a plurality of inks which are pushed out from the ink reservoir due to expansion of air in the ink reservoir at an outer peripheral portion. An ink reservoir that holds the ink is provided inside the ink reservoir groove formed between the wings through a vertical groove that connects the ink reservoir groove and the ink reservoir, and the nozzle and the ink from the nozzle are provided outside the shaft cylinder. An ink jet characterized in that a means for ejecting drops is provided, and an ink flow path for supplying ink from the ink reservoir to the means for ejecting the ink drops is provided near the boundary between the ink reservoir and the ink reservoir. head.