JPS6317053A - Ink jet recorder - Google Patents

Abstract

PURPOSE:To achieve the improvement in the efficiency of heat transfer to ink making the best use of the merits of a thermal electrostatic ink jet method, by a method wherein the opening for ink flying is provided by forming the recording sheet side of a head body by an organic resistant film and the electrode for application of current is arranged to a unit opening fringe part and heated by applying current according to picture information. CONSTITUTION:When a switching element 15 is turned on according to the picture information to be recorded, current is caused to flow to a corresponding through hole 13 fringe part via the electrode 14 for application of current and the ink unit area facing the corresponding penetrating hole 13 is joined by a thermal signal to be heated. Then, this heated ink unit area turns capable of flying by the decrease in the viscosity and surface tension of the ink 3 and the increase in its electric conductivity. Besides, when an electrostatic control pulse is applied to the electrode 22 for electrostatic induction synchronizing with the drive timing of a thermal signal application means 6, an electrostatic field is formed between the ink 3 facing an electric conductive layer 21 and the electrode 22 for electrostatic induction and the heated ink unit area flies toward a recording sheet 5 to be transferred by adhesion. Then, an ink dot is formed.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an inkjet recording device, and particularly to an improvement of an inkjet recording device that uses thermal energy and electrostatic energy to fly ink.

[Prior Art] A conventional inkjet recording device has a large number of ink ejection devices that closely connect ink with ejection ports (
It is known that the ink ejection device is provided with a plurality of orifices, respectively, and a pressure pulse is appropriately applied to the ink ejection device to eject ink from the ejection opening.

In this type, it is difficult to downsize the ink ejection device because it is necessary to maintain a large volume ratio between the ejection port and the ink ejection device in order to maintain the ink ejection operation from the ejection port. However, the pitch between the ejection ports has to be increased to some extent, making it impossible to set a high image recording density. Therefore, there is a problem that the recording speed inevitably decreases.

As a means to solve this problem, magnetic ink is placed near the magnetic electrode array, and the ink bulge caused by the magnetic field is used to form an ink ejection state corresponding to the image density, and the magnetic ink is transferred to the recording sheet using an electrostatic field. This is an application of the WIla inkjet method that allows it to fly to the side (
(Japanese Patent Application Laid-open No. 55-69469), a slit-shaped ink reservoir parallel to the electrode array is filled with ink, and an electric field pattern is formed between the electrode and the electrode array facing each other via the recording sheet. Applying the so-called plane scanning inkjet method in which the ink is ejected toward the recording sheet (Japanese Patent Laid-Open No. 56-37163), or by applying thermal energy to the ink, the ink is rapidly heated to cause film surface boiling. This is an application of the so-called thermal bubble jet method in which ink is ejected from the ejection port by increasing the pressure by rapidly growing bubbles within the ejection port (orifice) (Japanese Patent Application Laid-open No. 181664/1983). Public bulletin)
is provided. In each of the above-mentioned conventional inkjet recording methods, not only can the density of a recorded image be increased, but also high-speed recording can be performed because electronic scanning is enabled.

[Problems to be Solved by the Invention] However, in applications where the magnetic inkjet method described above is applied, it is necessary to use ink containing a large amount of magnetic powder, so it is necessary to use black ink as the ink. This causes a problem in that it becomes difficult to obtain a color image by overprinting ink. In addition, in the case of applying the above-mentioned plane scanning inkjet method,
Although it is possible to improve ink clogging by eliminating the need for a minute orifice, it is necessary to apply a high voltage to make the ink fly, so it is difficult to prevent voltage leaks between adjacent and nearby electrodes. , it is necessary to drive the electrode array in a time-division manner, which is not desirable for high-speed recording. Furthermore, in the case of applying the thermal bubble jet method mentioned above, it is necessary to rapidly raise the temperature of the heating element in order to cause film surface boiling, and as a result, thermal deterioration of the ink and heating There is a problem in that the heat-generating resistor protective layer provided as a means is likely to be thermally degraded.

In order to solve these problems, the inventors applied a thermal signal to the recording ink according to the image information, and at the same time, the heated ink portion was caused to fly toward the recording sheet based on a predetermined electrostatic field. A so-called thermostatic inkjet recording device has already been proposed.

According to this type, there is no need to use magnetic ink produced by the 11a inkjet method, and coloring based on overprinting of ink can be easily achieved, and it is also possible to use the so-called flat inkjet method. It is no longer necessary to make the ink fly using only an electrostatic field, and there is no need to increase the strength of the electrostatic field to an extremely large extent, making it possible to effectively prevent voltage leaks between the ink and the surrounding areas. Since there is no need to fly the ink using only thermal energy, thermal energy consumption can be suppressed to some extent, and thermal deterioration of the ink can be effectively prevented. Therefore, it is possible to perform high-speed, high-density recording while effectively preventing the drawbacks of conventional methods.

By the way, in such a thermoelectrostatic inkjet recording device, a heating array consisting of a plurality of heating resistors arranged according to the pixel density is usually used as a means for applying a thermal signal to the ink, and this heating array is used as a means for applying a thermal signal to the ink. It is disposed at an edge portion of the main body near the opening surface of the ink accommodating portion to indirectly heat the ink within the ink accommodating portion. At this time, when disposing the heat generating array at the edge near the opening surface of the ink storage section, for example, a photolithography process or the like is applied to the insulating substrate that constitutes one wall of the ink storage section. Since it is difficult to manufacture and place a heat generating array near the edge of the insulating substrate while maintaining the It is necessary to set the relative position of the heat generating array near the end of the insulating substrate by cutting. In addition, in order to maintain good quality of recorded images, it is necessary to stabilize the ink flying motion, and one way to achieve this is to form a stable ink meniscus. As described above, since the end portion of the head body is cut, the end surface inevitably becomes rough, and it is necessary to polish the end surface to keep the surface roughness to a small level. Therefore, a problem arises in that the manufacturing process of the head body becomes complicated.

Furthermore, since the heating array is assembled on the insulating substrate, the heat from the heating resistor inevitably escapes to the insulating substrate, which reduces the efficiency of heat transfer to the ink. There are also problems.

[Means for Solving the Problems] The present invention has been made in view of the above problems, and takes advantage of the so-called thermoelectrostatic inkjet method while improving productivity. An object of the present invention is to provide an inkjet recording device that improves the efficiency of heat transfer to ink.

In other words, the present invention provides a head body having an ink chamber, a thermal signal applying means for appropriately applying a thermal signal corresponding to image information to each ink unit area according to pixel density, and an ink surface and a recording sheet. and an electrostatic field forming means for forming a predetermined electrostatic field between the inkjet recording apparatus and the inkjet recording apparatus, the inkjet recording apparatus comprising an electrostatic field forming means for forming a predetermined electrostatic field between the inkjet recording apparatus and the inkjet recording apparatus, the ink unit area to which the thermal signal is applied based on the electrostatic field is caused to fly toward the recording sheet side, The recording sheet side of the head body is composed of an organic resistive film, and this organic resistive film is provided with openings for ink flying, and the thermal signal application means corresponds to the ink unit area of the openings for ink flying. A current-carrying electrode is disposed at the edge of the unit opening, and the edge of each unit opening is heated by electricity in accordance with image information.

In such technical means, the design of the head main body may be modified as appropriate as long as it has at least an ink chamber for storing ink, but the head main body may have an opening on the recording sheet side for ink to fly out. It is necessary to arrange an organic resistive film to In this case, the opening may be a through hole depending on the pixel density,
It may be a slit having an appropriately set width dimension.

At this time, the above-mentioned through holes are desirable in order to accurately partition the ink unit areas according to the pixels, but slits are desirable as the openings from the viewpoint of preventing ink clogging.

In addition, as the heat signal applying means, an organic resistor that can generate heat when energized is used, and energized resistors are arranged at the edges of the unit openings corresponding to the ink unit areas among the ink flying openings of this right separate resistor. It is necessary to apply a signal according to the image information to the electrode and design the corresponding part to function as a heating part. In this case, in order to maintain good heat transfer efficiency to the ink, it is desirable to insulate between the current-carrying electrode and the organic resistive film, which are exposed outside the edge of the ink-flying opening.

Furthermore, the design of the electrostatic field forming means may be changed as appropriate as long as it forms an electrostatic field to the extent that the ink heated between the ink surface and the recording sheet flies toward the recording sheet.

Furthermore, the ink to be used may be appropriately selected as long as it is in a state where it can fly when a predetermined thermal signal is applied. In this case, the specific conditions for ink flight are that the viscosity and surface tension of the ink are reduced to the extent that the ink can fly due to the acting electrostatic field, and that the electrical conductivity of the ink is improved. is necessary.

The organic resistive film constituting the recording sheet side of the head body is made by dispersing several tens of percent of a suitable conductive powder in a suitable resin material, and its volume resistivity is approximately 0.01 to 10.
A 4Ωcyr one is used. In this case, aromatic polyamide, polyimide, polysulfone, polyphenylene oxide, polycarbonite, polyester, and various fluorinated polymers are used as the resin material, and metal fine particles such as Ni, Cl, and AQ are used as the conductive powder. Powder, gold amide such as SnO, ZnO, Fe2O3, carbon, etc. are used.

[Operation] According to the above-mentioned technical means, when a signal corresponding to image information is applied to the current-carrying electrode, the unit opening edge of the organic resistive film is directly heated by electricity, and the unit opening edge The ink unit area facing is heated. Then, the viscosity and surface tension of the heated ink unit area decrease and its electrical conductivity improves, making the heated ink unit area easy to fly, and the above-mentioned heating is caused by the attractive force of the electrostatic field acting on the ink surface. The resulting ink unit area flies toward the recording sheet, and the raised end of the ink column comes into contact with and is transferred to the recording sheet, forming an ink dot.

[Example] Hereinafter, the present invention will be described in detail based on practical examples shown in the accompanying drawings.

1 to 3, the inkjet recording apparatus includes a head main body 1 having an ink chamber 2, a thermal signal applying means 4 for applying a thermal signal to ink 3 accommodated in the ink chamber 2, and an ink 3 An electrostatic field forming means 6 is provided for forming a predetermined electrostatic field between the surface and the recording sheet 5.

In this embodiment, the head main body 1 includes a base member 11 which is made of an insulating member such as alumina ceramics and has an open end that defines a box-shaped ink chamber 2.
and an organic resistance film 12 that closes the opening of the base member 11.

As the organic resistive film 12, for example, a conductive polyimide film having a thickness of about 30 μm and made of polyimide containing 48 mm % of carbon is used, and its volume resistivity is set to about 1 Ωα. In the organic resistor [12], through holes 13 for ink to fly are formed in accordance with the pixel density (for example, 6 holes/m, hole diameter 100 μm).

Further, ink 3 is supplied to the ink chamber 2 at an appropriate pressure by an ink supply means not shown, and the ink 3 is filled into the through hole 13 by capillary action. In this embodiment, the ink 3 accommodated in the ink chamber 2 is, for example, a Q74 ink having a volume resistivity of 107 Ωα or less, and its viscosity is 20 to 20 300CE
) S, and the viscosity decreases by one order of magnitude or more when heated (for example, to 200° C.).

Further, the thermal signal applying means 4 connects the organic resistive film 12 and eight pairs of current-carrying electrodes 14 (14a, 14b) disposed at both end edges of each through hole 13 of the organic resistor 11112.
), a switching element 15 interposed between the eight pairs of current-carrying electrodes 14 and turned on and off according to image information, and a current-carrying power source 1 connected in series with each switching element 15.
It consists of 6. In this embodiment, the current-carrying electrode 14 has an outer diameter of 1 disposed around the through hole 13.
It consists of a ring-shaped part 17 of 50 μm and a linear part 18 extending from one end of this ring-shaped part 17. Each of the opposing ring-shaped parts 17 is provided directly on the surface of the organic resistive film 12, while the opposing ring-shaped parts 17 are provided directly on the surface of the organic resistive film 12. Each linear portion 18 is provided on the organic resistance film 12 via an insulating layer 19 such as 5i02. For example, on the outer surface side of the organic resistor 11112, 5
An insulating coating 20 such as tO2 is provided with a thickness of about 10 μm. More specifically, the current-carrying electrode 14 and the insulating coating 2
Describing the manufacturing process of No. 0, for example, E organic resistive film 12
An insulating layer 19 is provided on both sides of the area excluding the area where the through hole 13 is formed.
After forming organic resistor FJ1 by sputtering,
2. A metal layer such as Cr, Cu, Aj, Au, etc. is vapor-deposited on the insulating layer 19, and the energizing electrode 14 of the above pattern is formed by a photolithography process, and then the insulating film 20 is formed by sputtering. At this stage, a method is adopted in which the through hole 13 is opened by means such as a laser, a micro drill, or plasma processing.

Further, the electrostatic field forming means 6 includes a conductive layer 21 formed using one of the current-carrying electrodes 14b, and a roll that is spaced a predetermined distance from the ink 3 surface and also functions as a support surface for the recording sheet 5. an electrostatic induction electrode 22 having a shape, and an electrostatic induction power supply that is interposed between the conductive layer 21 and the electrostatic induction electrode 22 to form an electrostatic field directed from the ink 3 surface toward the electrostatic induction electrode 22 side. It consists of 23. In this embodiment, the electrostatic control pulse applied by the electrostatic induction power supply 23 to the electrostatic induction electrode 22 is output at a timing synchronized with the drive pulse of the thermal signal application means 4. There is.

Therefore, according to the inkjet recording apparatus according to this embodiment, the switching element 1
5 is turned on, as shown in FIG. 2, a current a flows through the current-carrying electrode 14 to the edge of the corresponding through hole 13, and the edge of the through hole 13 is directly heated. ,
A thermal signal Q is applied to the ink unit area M facing the corresponding through hole 13.
is given and heated. Then, in this heated ink unit region M, the viscosity and surface tension of the ink 3 are reduced, and its electrical conductivity is improved, and the ink 3 changes into a state in which it can fly. On the other hand, the thermal signal applying means 4
When an electrostatic control pulse is applied to the electrostatic induction electrode 22 of the electrostatic field forming means 6 in synchronization with the driving timing of the An electric field S is formed, and the ink unit area M heated based on this electrostatic field S flies toward the recording sheet 5 passing in front of the electrostatic induction electrode 22.

At this point, as shown by the imaginary line in FIG. 2, when the end of the ink column 3a raised due to the above-mentioned flying motion comes into contact with the recording sheet 5, the ink 3 is attached and transferred to the recording sheet 5.
Ink dots D are formed on the recording sheet 5.

In the recording operation process of this embodiment, first, the through hole 1
Since the three edges are directly heated by electricity, the ink unit region M facing the through hole 13 is directly heated.Secondly, the organic resistive film 12, which is a heating element, supports a heating array. Since no substrate is attached, the heat generated in the paid resistive film 12 will not escape to the substrate side.Thirdly, since the edge of the through hole 13 is secured as a cylindrical peripheral surface, no heat will be generated on the flat surface. The heat generating area can be expanded compared to the case where a resistor is disposed. From these points, the efficiency of heat transfer to the ink unit area M is improved compared to the conventional type using a heat generating array.

In order to demonstrate such a recording operation process, the inventors of the present application set a drive pulse of 7 V,
0.5ms, 1000V/300 as electrostatic control pulse
It was confirmed that stable recording operation was performed at a repetition frequency of 500112 when pulses of 0.5 ms were synchronously applied, and that the thermal signal power was approximately 0.1 W/dot.

Further, in this embodiment, when manufacturing the head main body unit U of the inkjet recording apparatus, a through hole 13 for ink flying is opened in the organic resistance film 12, and at the same time, a through hole 13 for ink flying is provided at the edge of the through hole 13 for conducting electricity. An electrode 14 is provided, and further,
While the insulating HTA 20 is applied to the outer surface of the organic resistive film 12, the organic resistor 112 manufactured in this manner and the box-shaped base member 11 may be adhesively fixed. In the head body unit U manufactured in this way, the edge of the through hole 13 of the organic resistive film 12 functions as a heat generating part, so the heat generating resistor is placed at the edge of the substrate as before. It is possible to omit the process of cutting the substrate when disposing it, and it is also possible to suppress the surface roughness of the resistive film 12 to an extremely small level during manufacturing. Insulating cover placed on [
The surface roughness of the head body 120 can also be kept extremely small, and the polishing process for the end surface of the head body 1 can also be omitted. Therefore, some of the work steps when manufacturing the ped body unit U are reduced compared to before, and manufacturing workability can be improved accordingly. Furthermore, since the surface roughness of the end surface of the head body 1 can be suppressed to an extremely small level, it is possible to maintain the ink meniscus of the ink unit area MM facing the through hole 13 in a stable state. Become.

Furthermore, in this embodiment, the organic resistive film 12 is made of a polyimide film having appropriate elasticity, so even if the organic resistive film 12 expands due to heating or deforms due to impact load, A certain degree of deformation will be absorbed by the elastic deformation valve. Therefore, when the rigid base member 11, which is one of the constituent members of the head body 1, and the organic resistive film 12 are bonded together, the sealing and bonding conditions between them are maintained at a good quality.

Furthermore, since the insulating film 20 is provided on the outer surface of the organic resistive film 12, the discharge phenomenon between the current-carrying electrode 14 and the static induction electrode 22 is effectively prevented, and the insulation film 20 is The ink meniscus in the through hole 13 is placed closer to the electrostatic induction electrode 22 by the thickness of the coating 20, and
The strength of the electrostatic field S acting on the ink meniscus becomes stronger, and charges can be easily induced into the ink meniscus.

In the above embodiment, the through hole 13 is used as the opening for the ink to fly, but the invention is not limited to this. For example, as shown in FIG. A slit 25 is opened in the organic resistor [12], and eight pairs of current-carrying electrodes 26 are provided at both edges of each unit opening 25a of the slit 25 corresponding to the ink unit area M according to the pixel density.
(specifically 26a, 26b), 27 (27a
, 27b) The edges of each of the unit openings 25a may be electrically heated via the electrodes 26 and 27 for heating. According to this type, since there is no orifice portion that directly partitions the ink unit area M, clogging of the ink 3 can be more effectively prevented than in the embodiment.

Further, in the above embodiment, a conductive polyimide film having a predetermined conductivity and volume resistivity is used as the organic resistive film 12, but the present invention is not limited to this. A resin film with a thickness of about 20 μm containing 40% by weight of carbon in polyester and a volume resistivity of 30Ωα, or a resin film with a thickness of about 50 μm containing 20% by weight of 5NO2 powder in polyester and a volume resistivity of 30Ωα. Resistivity is 3 x 1
It has been confirmed that even if a 03Ω opening is used, the same effect as in the example is obtained.

Furthermore, as another modification of the above embodiment, the through hole 1
Alternatively, the arrangement of the third group may be arranged in a staggered or diagonal manner instead of in a straight line, or one of the current-carrying electrodes 14 may be made into a uniform electrode, or
As the conductive electrode 21 of the electrostatic field forming means 6, various methods may be used, such as providing one of the current-carrying electrodes 14a separately without using it in combination.

[Effects of the Invention] As described above, according to the inkjet recording apparatus according to the present invention, the following effects can be achieved while taking advantage of the so-called thermoelectrostatic inkjet method.

First, an opening for ink flight was created in the organic resistive film that constitutes a part of the head body, and the edge of this opening was appropriately heated with electricity to directly heat the ink unit area. Compared to the type in which a heat generating array is disposed above, the heat transfer path is more direct, and there is no loss of heat to the substrate, etc., so the efficiency of heat transfer to the ink can be improved.

Second, when manufacturing the head body unit, the opening edge of the organic resistive film, which is a component of the head body, can be easily constructed as a heat generating part, and the end surface of the head body can be easily constructed without going through a polishing process. Since it can be formed to be smooth, the manufacturing process can be reduced compared to a type in which a heat generating array is disposed on a substrate, and the manufacturing workability of the head body unit can be improved.

[Brief explanation of the drawing]

FIG. 1 is a perspective explanatory view showing an embodiment of an inkjet recording apparatus according to the present invention, and FIGS. 2 and 3 are
4 are perspective explanatory views showing a modification of the inkjet recording apparatus according to the present invention. [Explanation of symbols] (1)...Head body (2)...Ink chamber (3)...Ink (4)...Heat signal application means (5)...Recording sheet (6) ...Electrostatic field forming means (12)...Organic resistance film (13)...Through hole (opening) (14)...Electrifying electrode (25)...Slit (opening) (26, 27) ... Current-carrying electrode patent applicant Fuji Xerox Co., Ltd. Agent
Patent attorney Tomohiro Nakamura (2 others) 1: To 7 done body 2: In 2! ! 3 in 2 Figure 2*3 Figure

Claims (1)

[Scope of Claims] 1) A head body having an ink chamber, a thermal signal applying means for appropriately applying a thermal signal corresponding to image information to each ink unit area according to pixel density, an ink surface and a recording sheet. and an electrostatic field forming means for forming a predetermined electrostatic field between the inkjet recording apparatus and the inkjet recording apparatus, the inkjet recording apparatus comprising an electrostatic field forming means for forming a predetermined electrostatic field between the inkjet recording apparatus and the inkjet recording apparatus, the ink unit area to which the thermal signal is applied based on the electrostatic field is caused to fly toward the recording sheet side, The recording sheet side of the head body is composed of an organic resistive film, and this organic resistive film is provided with openings for ink flying, and the thermal signal application means corresponds to the ink unit area of the openings for ink flying. An inkjet recording apparatus characterized in that a current-carrying electrode is disposed at the edge of each unit opening, and the edge of each unit opening is heated by electricity in accordance with image information. 2) The inkjet recording apparatus according to claim 1, wherein the organic resistive film is made of a conductive polyimide film. 3) The inkjet recording apparatus according to claim 1, wherein the opening is formed of a through hole depending on the pixel density. 4) The inkjet recording apparatus according to claim 1, wherein the opening is a slit.